Gastos_casa %>%
dplyr::select(-Tiempo,-link) %>%
dplyr::select(fecha, gasto, monto, gastador,obs) %>% tail(30) %>%
knitr::kable(format = "markdown", size=12)
| fecha | gasto | monto | gastador | obs |
|---|---|---|---|---|
| 30/9/2022 | Comida | 28000 | Andrés | Caramagnola |
| 2/10/2022 | Enceres | 10000 | Andrés | Manguera |
| 2/10/2022 | Electricidad | 48087 | Andrés | atrasado del mes anterior |
| 4/10/2022 | Comida | 41760 | Andrés | NA |
| 4/10/2022 | Comida | 12860 | Andrés | NA |
| 8/10/2022 | Brussels | 25300 | Tami | NA |
| 8/10/2022 | Comida | 25300 | Tami | NA |
| 10/10/2022 | Comida | 67895 | Tami | NA |
| 11/10/2022 | Enceres | 11730 | Andrés | Ida easy |
| 11/10/2022 | Enceres | 7146 | Andrés | Uber easy |
| 15/10/2022 | Tres toques | 28600 | Tami | NA |
| 17/10/2022 | Comida | 47140 | Andrés | NA |
| 19/10/2022 | Comida | 28110 | Andrés | FREST verduras y frutas |
| 23/10/2022 | Comida | 76701 | Tami | NA |
| 26/10/2022 | Comida | 35941 | Tami | NA |
| 26/10/2022 | Enceres | 11980 | Andrés | Mascarilla |
| 27/10/2022 | Comida | 17536 | Tami | NA |
| 30/10/2022 | VTR | 21990 | Andrés | entel |
| 28/10/2022 | Comida | 27940 | Andrés | tres toques |
| 3/11/2022 | Diosi | 56000 | Tami | Vacunas |
| 4/11/2022 | Electricidad | 49266 | Andrés | Pac enel |
| 6/11/2022 | Comida | 19325 | Tami | NA |
| 8/11/2022 | Agua | 10092 | Andrés | NA |
| 9/11/2022 | Diosi | 117980 | Andrés | 58990 por 2 |
| 9/11/2022 | Comida | 73462 | Tami | NA |
| 9/11/2022 | Diosi | 17535 | Tami | Correa petsu |
| 12/11/2022 | Gas | 76350 | Andrés | NA |
| 12/11/2022 | Enceres | 16986 | Andrés | uber ida matri fran |
| 31/3/2019 | Comida | 9000 | Andrés | NA |
| 8/9/2019 | Comida | 24588 | Andrés | Super Lider |
#para ver las diferencias depués de la diosi
Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(gastador=ifelse(gastador=="Andrés",1,0)) %>%
dplyr::group_by(gastador, fecha,.drop = F) %>%
dplyr::summarise(gasto_media=mean(monto,na.rm=T)) %>%
dplyr::mutate(treat=ifelse(fecha>"2019-W26",1,0)) %>%
#dplyr::mutate(fecha_simp=lubridate::week(fecha)) %>%#después de diosi. Junio 24, 2019
dplyr::mutate(gastador_nombre=plyr::revalue(as.character(gastador), c("0" = "Tami", "1"="Andrés"))) %>%
assign("ts_gastos_casa_week_treat", ., envir = .GlobalEnv)
gplots::plotmeans(gasto_media ~ gastador_nombre, main="Promedio de gasto por gastador", data=ts_gastos_casa_week_treat,ylim=c(0,75000), xlab="", ylab="")
par(mfrow=c(1,2))
gplots::plotmeans(gasto_media ~ gastador_nombre, main="Antes de Diosi", data=ts_gastos_casa_week_treat[ts_gastos_casa_week_treat$treat==0,], xlab="", ylab="", ylim=c(0,70000))
gplots::plotmeans(gasto_media ~ gastador_nombre, main="Después de Diosi", data=ts_gastos_casa_week_treat[ts_gastos_casa_week_treat$treat==1,], xlab="", ylab="",ylim=c(0,70000))
library(ggiraph)
library(scales)
#if( requireNamespace("dplyr", quietly = TRUE)){
gg <- Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(gastador=ifelse(gastador=="Andrés",1,0)) %>%
dplyr::mutate(fecha_simp=tsibble::yearweek(fecha)) %>%
dplyr::mutate(fecha_week=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(treat=ifelse(fecha_week>"2019 W26",1,0)) %>%
dplyr::mutate(gastador_nombre=plyr::revalue(as.character(gastador), c("0" = "Tami", "1"="Andrés"))) %>%
# dplyr::mutate(week=as.Date(as.character(lubridate::floor_date(fecha, "week"))))%>%
#dplyr::mutate(fecha_week= lubridate::parse_date_time(fecha_week, c("%Y-W%V"),exact=T)) %>%
dplyr::group_by(gastador_nombre, fecha_simp) %>%
dplyr::summarise(monto_total=sum(monto)) %>%
dplyr::mutate(tooltip= paste0(substr(gastador_nombre,1,1),"=",round(monto_total/1000,2))) %>%
ggplot(aes(hover_css = "fill:none;")) +#, ) +
#stat_summary(geom = "line", fun.y = median, size = 1, alpha=0.5, aes(color="blue")) +
geom_line(aes(x = fecha_simp, y = monto_total, color=as.factor(gastador_nombre)),size=1,alpha=.5) +
ggiraph::geom_point_interactive(aes(x = fecha_simp, y = monto_total, color=as.factor(gastador_nombre),tooltip=tooltip),size = 1) +
#geom_text(aes(x = fech_ing_qrt, y = perc_dup-0.05, label = paste0(n)), vjust = -1,hjust = 0, angle=45, size=3) +
# guides(color = F)+
sjPlot::theme_sjplot2() +
geom_vline(xintercept = as.Date("2019-06-24"),linetype = "dashed") +
labs(y="Gastos (en miles)",x="Semanas y Meses", subtitle="Interlineado, incorporación de la Diosi; Azul= Tami; Rojo= Andrés") + ggtitle( "Figura 4. Gastos por Gastador") +
scale_y_continuous(labels = f <- function(x) paste0(x/1000)) +
scale_color_manual(name = "Gastador", values= c("blue", "red"), labels = c("Tami", "Andrés")) +
scale_x_yearweek(date_breaks = "1 month", minor_breaks = "1 week", labels=scales::date_format("%m/%y")) +
theme(axis.text.x = element_text(vjust = 0.5,angle = 35), legend.position='bottom')+
theme(
panel.border = element_blank(),
panel.grid.major = element_blank(),
panel.grid.minor = element_blank(),
axis.line = element_line(colour = "black")
)
# x <- girafe(ggobj = gg)
# x <- girafe_options(x = x,
# opts_hover(css = "stroke:red;fill:orange") )
# if( interactive() ) print(x)
#}
tooltip_css <- "background-color:gray;color:white;font-style:italic;padding:10px;border-radius:10px 20px 10px 20px;"
#ggiraph(code = {print(gg)}, tooltip_extra_css = tooltip_css, tooltip_opacity = .75 )
x <- girafe(ggobj = gg)
x <- girafe_options(x,
opts_zoom(min = 1, max = 3), opts_hover(css =tooltip_css))
x
plot<-Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_week=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(month=as.Date(as.character(lubridate::floor_date(fecha, "month"))))%>%
dplyr::group_by(month)%>%
dplyr::summarise(gasto_total=sum(monto)/1000) %>%
ggplot2::ggplot(aes(x = month, y = gasto_total)) +
geom_point()+
geom_line(size=1) +
sjPlot::theme_sjplot2() +
geom_vline(xintercept = as.Date("2019-06-24"),linetype = "dashed") +
geom_vline(xintercept = as.Date("2019-03-23"),linetype = "dashed", color="red") +
labs(y="Gastos (en miles)",x="Meses/Año", subtitle="Interlineado, incorporación de la Diosi") +
ggtitle( "Figura. Suma de Gastos por Mes") +
scale_x_date(breaks = "1 month", minor_breaks = "1 month", labels=scales::date_format("%m/%y")) +
theme(axis.text.x = element_text(vjust = 0.5,angle = 45))
plotly::ggplotly(plot)
plot2<-Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_week=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(day=as.Date(as.character(lubridate::floor_date(fecha, "day"))))%>%
dplyr::group_by(day)%>%
summarise(gasto_total=sum(monto)/1000) %>%
ggplot2::ggplot(aes(x = day, y = gasto_total)) +
geom_line(size=1) +
sjPlot::theme_sjplot2() +
geom_vline(xintercept = as.Date("2019-06-24"),linetype = "dashed") +
geom_vline(xintercept = as.Date("2020-03-23"),linetype = "dashed", color="red") +
labs(y="Gastos (en miles)",x="Meses/Año", subtitle="Interlineado, incorporación de la Diosi") +
ggtitle( "Figura. Suma de Gastos por Día") +
scale_x_date(breaks = "1 month", minor_breaks = "1 week", labels=scales::date_format("%m/%y")) +
theme(axis.text.x = element_text(vjust = 0.5,angle = 45))
plotly::ggplotly(plot2)
tsData <- Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_week=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(day=as.Date(as.character(lubridate::floor_date(fecha, "day"))))%>%
dplyr::group_by(day)%>%
summarise(gasto_total=sum(monto))%>%
dplyr::mutate(covid=case_when(day>as.Date("2019-06-02")~1,TRUE~0))%>%
dplyr::mutate(covid=case_when(day>as.Date("2020-03-10")~covid+1,TRUE~covid))%>%
dplyr::mutate(covid=as.factor(covid))%>%
data.frame()
tsData_gastos <-ts(tsData$gasto_total, frequency=7)
mstsData_gastos <- forecast::msts(Gastos_casa$monto, seasonal.periods=c(7,30))
tsData_gastos = decompose(tsData_gastos)
#plot(tsData_Santiago, title="Descomposición del número de casos confirmados para Santiago")
forecast::autoplot(tsData_gastos, main="Descomposición de los Gastos Diarios")+
theme_bw()+ labs(x="Weeks")
tsdata_gastos_trend<-cbind(tsData,trend=as.vector(tsData_gastos$trend))%>% na.omit()
#tsData_gastos$trend
#Using the inputted variables, a Type-2 Sum Squares ANCOVA Lagged Dependent Variable model is fitted which estimates the difference in means between interrupted and non-interrupted time periods, while accounting for the lag of the dependent variable and any further specified covariates.
#Typically such analyses use Auto-regressive Integrated Moving Average (ARIMA) models to handle the serial dependence of the residuals of a linear model, which is estimated either as part of the ARIMA process or through a standard linear regression modeling process [9,17]. All such time series methods enable the effect of the event to be separated from general trends and serial dependencies in time, thereby enabling valid statistical inferences to be made about whether an intervention has had an effect on a time series.
#it uses Type-2 Sum Squares ANCOVA Lagged Dependent Variable model
#ITSA model da cuenta de observaciones autocorrelacionadas e impactos dinámicos mediante una regresión de deltas en rezagados. Una vez que se incorporan en el modelo, se controlan.
#residual autocorrelation assumptions
#TSA allows the model to account for baseline levels and trends present in the data therefore allowing us to attribute significant changes to the interruption
#RDestimate(all~agecell,data=metro_region,cutpoint = 21)
tsdata_gastos_trend<-cbind(tsData,trend=as.vector(tsData_gastos$trend))%>% na.omit()
itsa_metro_region_quar2<-
its.analysis::itsa.model(time = "day", depvar = "trend",data=tsdata_gastos_trend,
interrupt_var = "covid",
alpha = 0.05,no.plots = F, bootstrap = TRUE, Reps = 10000, print = F)
print(itsa_metro_region_quar2)
## [[1]]
## [1] "ITSA Model Fit"
##
## $aov.result
## Anova Table (Type II tests)
##
## Response: depvar
## Sum Sq Df F value Pr(>F)
## interrupt_var 4.7512e+08 2 5.2218 0.0057 **
## lag_depvar 7.7416e+10 1 1701.6794 <2e-16 ***
## Residuals 2.3338e+10 513
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## $tukey.result
## Tukey multiple comparisons of means
## 95% family-wise confidence level
##
## Fit: stats::aov(formula = x$depvar ~ x$interrupt_var)
##
## $`x$interrupt_var`
## diff lwr upr p adj
## 1-0 7228.838 975.1541 13482.52 0.018644
## 2-0 27242.124 21490.2953 32993.95 0.000000
## 2-1 20013.285 16545.5670 23481.00 0.000000
##
##
## $data
## depvar interrupt_var lag_depvar
## 2 19269.29 0 16010.00
## 3 24139.00 0 19269.29
## 4 23816.14 0 24139.00
## 5 26510.14 0 23816.14
## 6 23456.71 0 26510.14
## 7 24276.71 0 23456.71
## 8 18818.71 0 24276.71
## 9 18517.14 0 18818.71
## 10 15475.29 0 18517.14
## 11 16365.29 0 15475.29
## 12 12621.29 0 16365.29
## 13 12679.86 0 12621.29
## 14 13440.71 0 12679.86
## 15 15382.86 0 13440.71
## 16 13459.71 0 15382.86
## 17 14644.14 0 13459.71
## 18 13927.00 0 14644.14
## 19 22034.57 0 13927.00
## 20 20986.00 0 22034.57
## 21 20390.57 0 20986.00
## 22 22554.14 0 20390.57
## 23 21782.57 0 22554.14
## 24 22529.57 0 21782.57
## 25 24642.71 0 22529.57
## 26 17692.29 0 24642.71
## 27 19668.29 0 17692.29
## 28 28640.00 0 19668.29
## 29 28706.00 0 28640.00
## 30 28331.57 0 28706.00
## 31 25617.86 0 28331.57
## 32 27223.29 0 25617.86
## 33 31622.57 0 27223.29
## 34 32021.43 0 31622.57
## 35 33634.57 0 32021.43
## 36 30784.86 0 33634.57
## 37 34770.57 0 30784.86
## 38 38443.00 1 34770.57
## 39 35073.00 1 38443.00
## 40 31422.29 1 35073.00
## 41 30103.29 1 31422.29
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## 279 67969.43 2 61395.43
## 280 60792.57 2 67969.43
## 281 56859.14 2 60792.57
## 282 44899.43 2 56859.14
## 283 43064.14 2 44899.43
## 284 62790.29 2 43064.14
## 285 69120.71 2 62790.29
## 286 69589.43 2 69120.71
## 287 66633.29 2 69589.43
## 288 65588.57 2 66633.29
## 289 70168.57 2 65588.57
## 290 74644.71 2 70168.57
## 291 52891.00 2 74644.71
## 292 41560.57 2 52891.00
## 293 34704.86 2 41560.57
## 294 46520.00 2 34704.86
## 295 50231.00 2 46520.00
## 296 49216.71 2 50231.00
## 297 76914.86 2 49216.71
## 298 83720.71 2 76914.86
## 299 84485.00 2 83720.71
## 300 89765.00 2 84485.00
## 301 87702.86 2 89765.00
## 302 82013.86 2 87702.86
## 303 85982.43 2 82013.86
## 304 57248.43 2 85982.43
## 305 52968.43 2 57248.43
## 306 52601.86 2 52968.43
## 307 45493.29 2 52601.86
## 308 42298.86 2 45493.29
## 309 46423.71 2 42298.86
## 310 37898.00 2 46423.71
## 311 36435.14 2 37898.00
## 312 30209.57 2 36435.14
## 313 34541.86 2 30209.57
## 314 33604.71 2 34541.86
## 315 37990.71 2 33604.71
## 316 35683.43 2 37990.71
## 317 65201.86 2 35683.43
## 318 62730.57 2 65201.86
## 319 64589.14 2 62730.57
## 320 73744.86 2 64589.14
## 321 76477.71 2 73744.86
## 322 105647.43 2 76477.71
## 323 103790.29 2 105647.43
## 324 76122.29 2 103790.29
## 325 74746.14 2 76122.29
## 326 72865.71 2 74746.14
## 327 63652.57 2 72865.71
## 328 60358.29 2 63652.57
## 329 25957.14 2 60358.29
## 330 30178.43 2 25957.14
## 331 30681.57 2 30178.43
## 332 33337.29 2 30681.57
## 333 32582.71 2 33337.29
## 334 39184.43 2 32582.71
## 335 40415.71 2 39184.43
## 336 34975.43 2 40415.71
## 337 34076.14 2 34975.43
## 338 34221.14 2 34076.14
## 339 28862.57 2 34221.14
## 340 35729.86 2 28862.57
## 341 36489.29 2 35729.86
## 342 36785.14 2 36489.29
## 343 37787.71 2 36785.14
## 344 39832.14 2 37787.71
## 345 41917.86 2 39832.14
## 346 41633.57 2 41917.86
## 347 33557.00 2 41633.57
## 348 22759.57 2 33557.00
## 349 28877.86 2 22759.57
## 350 27574.00 2 28877.86
## 351 27104.71 2 27574.00
## 352 24376.14 2 27104.71
## 353 29732.29 2 24376.14
## 354 34030.00 2 29732.29
## 355 39139.71 2 34030.00
## 356 37066.57 2 39139.71
## 357 38509.29 2 37066.57
## 358 40957.29 2 38509.29
## 359 49423.00 2 40957.29
## 360 50053.29 2 49423.00
## 361 50284.14 2 50053.29
## 362 53103.86 2 50284.14
## 363 50223.00 2 53103.86
## 364 49587.14 2 50223.00
## 365 41167.71 2 49587.14
## 366 37958.71 2 41167.71
## 367 33582.29 2 37958.71
## 368 31039.43 2 33582.29
## 369 26526.57 2 31039.43
## 370 34869.43 2 26526.57
## 371 37487.43 2 34869.43
## 372 46514.43 2 37487.43
## 373 39613.43 2 46514.43
## 374 38980.57 2 39613.43
## 375 37306.14 2 38980.57
## 376 36771.29 2 37306.14
## 377 26317.00 2 36771.29
## 378 31580.71 2 26317.00
## 379 23626.57 2 31580.71
## 380 33035.71 2 23626.57
## 381 44864.57 2 33035.71
## 382 48946.14 2 44864.57
## 383 46969.57 2 48946.14
## 384 49249.57 2 46969.57
## 385 56370.14 2 49249.57
## 386 67228.71 2 56370.14
## 387 59457.29 2 67228.71
## 388 53124.71 2 59457.29
## 389 52814.14 2 53124.71
## 390 61262.00 2 52814.14
## 391 61861.14 2 61262.00
## 392 71784.71 2 61861.14
## 393 59313.29 2 71784.71
## 394 61107.00 2 59313.29
## 395 60603.43 2 61107.00
## 396 60012.57 2 60603.43
## 397 58280.43 2 60012.57
## 398 56862.71 2 58280.43
## 399 41704.43 2 56862.71
## 400 51533.00 2 41704.43
## 401 50388.71 2 51533.00
## 402 49205.29 2 50388.71
## 403 56533.29 2 49205.29
## 404 47996.14 2 56533.29
## 405 47207.57 2 47996.14
## 406 45292.00 2 47207.57
## 407 40343.43 2 45292.00
## 408 39004.86 2 40343.43
## 409 36788.43 2 39004.86
## 410 30027.57 2 36788.43
## 411 39040.14 2 30027.57
## 412 42390.14 2 39040.14
## 413 36291.14 2 42390.14
## 414 30668.29 2 36291.14
## 415 47693.00 2 30668.29
## 416 52094.43 2 47693.00
## 417 56592.57 2 52094.43
## 418 47971.43 2 56592.57
## 419 43762.43 2 47971.43
## 420 42246.71 2 43762.43
## 421 46352.43 2 42246.71
## 422 33094.86 2 46352.43
## 423 32784.86 2 33094.86
## 424 26212.43 2 32784.86
## 425 32611.57 2 26212.43
## 426 42144.86 2 32611.57
## 427 50034.86 2 42144.86
## 428 46332.00 2 50034.86
## 429 42976.29 2 46332.00
## 430 39456.29 2 42976.29
## 431 39328.29 2 39456.29
## 432 35296.14 2 39328.29
## 433 30875.43 2 35296.14
## 434 27709.00 2 30875.43
## 435 29513.29 2 27709.00
## 436 31630.43 2 29513.29
## 437 29346.14 2 31630.43
## 438 34916.86 2 29346.14
## 439 42020.86 2 34916.86
## 440 38303.00 2 42020.86
## 441 37966.43 2 38303.00
## 442 41408.14 2 37966.43
## 443 38988.14 2 41408.14
## 444 43555.29 2 38988.14
## 445 38114.00 2 43555.29
## 446 27847.86 2 38114.00
## 447 26517.00 2 27847.86
## 448 39518.29 2 26517.00
## 449 39153.71 2 39518.29
## 450 45623.14 2 39153.71
## 451 40627.43 2 45623.14
## 452 41027.71 2 40627.43
## 453 42882.86 2 41027.71
## 454 47139.43 2 42882.86
## 455 35547.57 2 47139.43
## 456 41099.00 2 35547.57
## 457 35859.57 2 41099.00
## 458 44524.57 2 35859.57
## 459 48554.29 2 44524.57
## 460 51554.29 2 48554.29
## 461 47810.29 2 51554.29
## 462 50490.00 2 47810.29
## 463 50720.71 2 50490.00
## 464 52720.71 2 50720.71
## 465 52145.57 2 52720.71
## 466 55515.57 2 52145.57
## 467 52457.00 2 55515.57
## 468 58239.57 2 52457.00
## 469 50523.57 2 58239.57
## 470 47788.57 2 50523.57
## 471 46170.00 2 47788.57
## 472 42305.57 2 46170.00
## 473 46605.57 2 42305.57
## 474 55149.57 2 46605.57
## 475 48769.57 2 55149.57
## 476 50719.43 2 48769.57
## 477 44753.71 2 50719.43
## 478 42898.00 2 44753.71
## 479 46141.14 2 42898.00
## 480 34022.57 2 46141.14
## 481 26651.86 2 34022.57
## 482 28791.86 2 26651.86
## 483 31879.00 2 28791.86
## 484 33584.71 2 31879.00
## 485 34690.43 2 33584.71
## 486 27410.43 2 34690.43
## 487 41755.00 2 27410.43
## 488 49379.57 2 41755.00
## 489 57198.86 2 49379.57
## 490 51144.57 2 57198.86
## 491 56677.43 2 51144.57
## 492 65416.43 2 56677.43
## 493 69779.71 2 65416.43
## 494 54046.00 2 69779.71
## 495 43259.57 2 54046.00
## 496 40998.57 2 43259.57
## 497 41368.57 2 40998.57
## 498 42274.29 2 41368.57
## 499 35962.71 2 42274.29
## 500 38709.00 2 35962.71
## 501 44778.14 2 38709.00
## 502 51282.43 2 44778.14
## 503 52094.86 2 51282.43
## 504 52221.43 2 52094.86
## 505 45011.43 2 52221.43
## 506 46545.43 2 45011.43
## 507 42263.00 2 46545.43
## 508 45417.43 2 42263.00
## 509 45034.71 2 45417.43
## 510 37840.57 2 45034.71
## 511 39135.43 2 37840.57
## 512 38191.14 2 39135.43
## 513 39456.86 2 38191.14
## 514 42479.14 2 39456.86
## 515 34282.57 2 42479.14
## 516 28878.43 2 34282.57
## 517 56227.14 2 28878.43
## 518 65569.43 2 56227.14
##
## $alpha
## [1] 0.05
##
## $itsa.result
## [1] "Significant variation between time periods with chosen alpha"
##
## $group.means
## interrupt_var count mean s.d.
## 1 0 37 22066.04 6308.636
## 2 1 120 29463.10 9187.258
## 3 2 361 49476.39 15751.147
##
## $dependent
## [1] 19269.29 24139.00 23816.14 26510.14 23456.71 24276.71 18818.71
## [8] 18517.14 15475.29 16365.29 12621.29 12679.86 13440.71 15382.86
## [15] 13459.71 14644.14 13927.00 22034.57 20986.00 20390.57 22554.14
## [22] 21782.57 22529.57 24642.71 17692.29 19668.29 28640.00 28706.00
## [29] 28331.57 25617.86 27223.29 31622.57 32021.43 33634.57 30784.86
## [36] 34770.57 38443.00 35073.00 31422.29 30103.29 19319.29 27926.29
## [43] 30715.43 31962.29 39790.14 39211.57 44548.57 49398.00 41039.00
## [50] 34821.29 29123.57 21275.71 28476.14 24561.86 20323.57 25370.00
## [57] 26811.86 27151.86 27623.29 22896.57 41889.29 44000.14 38558.00
## [64] 43373.86 49001.00 61213.29 58939.57 42046.86 39191.71 42646.43
## [71] 36121.57 30915.57 20273.43 23938.29 19274.29 21662.29 15819.00
## [78] 18126.14 17240.71 16127.71 13917.14 15379.86 19510.14 24567.29
## [85] 25700.43 25729.00 26435.00 31157.14 29818.43 30962.43 28746.71
## [92] 27830.71 28252.14 28717.57 21365.43 24816.86 16838.57 15529.14
## [99] 13286.29 13629.43 14404.86 19524.86 18475.71 22495.00 22254.57
## [106] 24173.29 27466.43 24602.43 20531.14 20846.43 23875.71 36312.71
## [113] 34244.00 36347.43 39779.71 42018.71 39372.57 33444.00 29255.86
## [120] 31640.14 29671.14 31023.71 39723.43 39314.14 38239.86 34649.43
## [127] 36688.43 42867.57 42226.86 32155.14 33603.00 37254.43 33145.57
## [134] 31299.43 30252.00 26310.71 27929.86 27666.14 25017.57 27335.00
## [141] 25760.71 18436.86 21906.00 19418.14 22826.14 23444.29 25264.86
## [148] 25473.29 27366.86 28855.86 32326.86 27141.43 26297.71 23499.14
## [155] 30246.29 39931.86 38020.43 35004.00 40750.86 42363.29 46273.57
## [162] 41083.29 35711.29 41921.71 60583.29 63115.57 61300.14 57666.43
## [169] 55834.00 58927.71 57810.57 48987.14 52219.29 56503.57 56545.00
## [176] 64705.57 53833.29 50114.00 39592.43 29907.29 33923.29 45489.00
## [183] 44866.29 51680.57 58257.00 70600.57 76648.00 69430.14 69651.57
## [190] 77745.14 72795.86 67670.71 55357.86 48524.00 50154.43 45111.57
## [197] 36147.00 43501.57 41472.43 41058.00 41605.57 49382.86 59558.57
## [204] 59134.57 61109.00 63004.43 67344.29 78180.86 69117.86 55597.57
## [211] 49426.14 39119.43 35636.86 39201.14 27777.00 47207.00 55587.29
## [218] 56619.71 82679.86 91259.57 93552.71 102242.71 91884.00 85013.86
## [225] 84535.29 80700.43 79740.57 85163.14 86724.86 80355.00 74875.14
## [232] 81347.00 66062.43 56946.43 47732.14 38129.71 42928.29 45392.57
## [239] 37895.43 30660.29 42430.86 35845.14 40350.43 31494.71 30013.29
## [246] 34197.57 37430.14 26932.43 33729.86 38081.43 44028.00 47139.71
## [253] 46558.86 58350.57 78380.00 78168.29 70510.86 72207.14 67881.00
## [260] 69536.43 62390.71 50113.14 45565.57 45805.29 41348.57 51426.86
## [267] 47160.57 51907.43 49751.43 54407.43 54746.29 61634.57 58926.43
## [274] 69999.29 63044.86 63285.29 61395.43 67969.43 60792.57 56859.14
## [281] 44899.43 43064.14 62790.29 69120.71 69589.43 66633.29 65588.57
## [288] 70168.57 74644.71 52891.00 41560.57 34704.86 46520.00 50231.00
## [295] 49216.71 76914.86 83720.71 84485.00 89765.00 87702.86 82013.86
## [302] 85982.43 57248.43 52968.43 52601.86 45493.29 42298.86 46423.71
## [309] 37898.00 36435.14 30209.57 34541.86 33604.71 37990.71 35683.43
## [316] 65201.86 62730.57 64589.14 73744.86 76477.71 105647.43 103790.29
## [323] 76122.29 74746.14 72865.71 63652.57 60358.29 25957.14 30178.43
## [330] 30681.57 33337.29 32582.71 39184.43 40415.71 34975.43 34076.14
## [337] 34221.14 28862.57 35729.86 36489.29 36785.14 37787.71 39832.14
## [344] 41917.86 41633.57 33557.00 22759.57 28877.86 27574.00 27104.71
## [351] 24376.14 29732.29 34030.00 39139.71 37066.57 38509.29 40957.29
## [358] 49423.00 50053.29 50284.14 53103.86 50223.00 49587.14 41167.71
## [365] 37958.71 33582.29 31039.43 26526.57 34869.43 37487.43 46514.43
## [372] 39613.43 38980.57 37306.14 36771.29 26317.00 31580.71 23626.57
## [379] 33035.71 44864.57 48946.14 46969.57 49249.57 56370.14 67228.71
## [386] 59457.29 53124.71 52814.14 61262.00 61861.14 71784.71 59313.29
## [393] 61107.00 60603.43 60012.57 58280.43 56862.71 41704.43 51533.00
## [400] 50388.71 49205.29 56533.29 47996.14 47207.57 45292.00 40343.43
## [407] 39004.86 36788.43 30027.57 39040.14 42390.14 36291.14 30668.29
## [414] 47693.00 52094.43 56592.57 47971.43 43762.43 42246.71 46352.43
## [421] 33094.86 32784.86 26212.43 32611.57 42144.86 50034.86 46332.00
## [428] 42976.29 39456.29 39328.29 35296.14 30875.43 27709.00 29513.29
## [435] 31630.43 29346.14 34916.86 42020.86 38303.00 37966.43 41408.14
## [442] 38988.14 43555.29 38114.00 27847.86 26517.00 39518.29 39153.71
## [449] 45623.14 40627.43 41027.71 42882.86 47139.43 35547.57 41099.00
## [456] 35859.57 44524.57 48554.29 51554.29 47810.29 50490.00 50720.71
## [463] 52720.71 52145.57 55515.57 52457.00 58239.57 50523.57 47788.57
## [470] 46170.00 42305.57 46605.57 55149.57 48769.57 50719.43 44753.71
## [477] 42898.00 46141.14 34022.57 26651.86 28791.86 31879.00 33584.71
## [484] 34690.43 27410.43 41755.00 49379.57 57198.86 51144.57 56677.43
## [491] 65416.43 69779.71 54046.00 43259.57 40998.57 41368.57 42274.29
## [498] 35962.71 38709.00 44778.14 51282.43 52094.86 52221.43 45011.43
## [505] 46545.43 42263.00 45417.43 45034.71 37840.57 39135.43 38191.14
## [512] 39456.86 42479.14 34282.57 28878.43 56227.14 65569.43
##
## $interrupt_var
## [1] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1
## [38] 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
## [75] 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
## [112] 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
## [149] 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [186] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [223] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [260] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [297] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [334] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [371] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [408] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [445] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## [482] 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## Levels: 0 1 2
##
## $residuals
## 2 3 4 5 6
## 2043.627141 4050.973709 -548.560653 2428.978730 -2990.372717
## 7 8 9 10 11
## 511.207278 -5666.932573 -1175.182896 -3952.194180 -390.776437
## 12 13 14 15 16
## -4916.391641 -1569.767039 -860.348457 413.594949 -3215.175307
## 17 18 19 20 21
## -341.805504 -2099.136428 6638.243721 -1530.553660 -1205.106533
## 22 23 24 25 26
## 1481.381777 -1190.279903 234.329040 1691.442058 -7114.789419
## 27 28 29 30 31
## 965.211307 8201.564196 388.431283 -43.959764 -2428.843641
## 32 33 34 35 36
## 1559.821274 4549.188583 1084.507971 2347.366776 -1919.040750
## 37 38 39 40 41
## 4569.347708 4281.003155 -2314.194606 -3005.309748 -1118.181893
## 42 43 44 45 46
## -10743.810596 7333.906664 2564.215744 1361.593714 8094.436812
## 47 48 49 50 51
## 641.289924 6486.402537 6648.774542 -5969.087372 -4845.766274
## 52 53 54 55 56
## -5082.963683 -7926.978000 6165.590417 -4072.250857 -4872.935192
## 57 58 59 60 61
## 3895.637822 905.623844 -20.642971 152.191028 -4988.540942
## 62 63 64 65 66
## 18155.265199 3586.353518 -3709.584886 5885.667314 7283.431335
## 67 68 69 70 71
## 14553.851417 1555.071748 -13340.822700 -1360.457328 4601.698606
## 72 73 74 75 76
## -4957.155403 -4432.899732 -10503.032755 2507.959963 -5374.588423
## 77 78 79 80 81
## 1109.426534 -6831.046942 607.782383 -2303.823644 -2639.223156
## 82 83 84 85 86
## -3872.336470 -468.255624 2377.446129 3807.292232 499.154475
## 87 88 89 90 91
## -467.422058 213.485961 4315.605971 -1170.185453 1149.499311
## 92 93 94 95 96
## -2070.897889 -1041.014773 184.862705 280.184559 -7480.706666
## 97 98 99 100 101
## 2427.515882 -8581.881121 -2884.624954 -3977.516614 -1664.653258
## 102 103 104 105 106
## -1190.579377 3248.424262 -2297.201567 2643.461685 -1126.781296
## 107 108 109 110 111
## 1003.082009 2611.172891 -3144.928824 -4700.994376 -810.226848
## 112 113 114 115 116
## 1942.168858 11718.791586 -1272.336513 2647.876934 4232.891016
## 117 118 119 120 121
## 3457.591354 -1154.884584 -4759.562204 -3741.119030 2321.274700
## 122 123 124 125 126
## -1741.651104 1340.134186 8851.994098 802.451128 87.608040
## 127 128 129 130 131
## -2559.362051 2632.821725 7021.275368 953.918379 -8555.108236
## 132 133 134 135 136
## 1737.923084 4117.815525 -3197.796774 -1435.461862 -861.572089
## 137 138 139 140 141
## -3882.985785 1197.470374 -488.206468 -2905.178913 1738.276285
## 142 143 144 145 146
## -1871.219998 -7812.508995 2088.586779 -3445.938681 2146.945553
## 147 148 149 150 151
## -227.883068 1049.823354 -340.609095 1369.916333 1195.945301
## 152 153 154 155 156
## 3359.276718 -4874.451150 -1164.221827 -3221.827061 5983.075322
## 157 158 159 160 161
## 9743.175469 -3136.137177 -4473.912228 3922.030795 487.458335
## 162 163 164 165 166
## 2981.678108 -5642.696108 -6456.486863 4471.735952 17679.188959
## 167 168 169 170 171
## 3822.521907 -216.808928 -2256.178750 -897.409194 3805.579285
## 172 173 174 175 176
## -28.523261 -7870.855380 3110.193009 4555.948387 834.834427
## 177 178 179 180 181
## 8959.022484 -9080.034807 -3251.069040 -10506.291859 -10951.187301
## 182 183 184 185 186
## 1570.492374 9609.277829 -1170.670313 6190.495124 6782.486258
## 187 188 189 190 191
## 13350.510990 8557.576526 -3971.249288 2589.040951 10488.149528
## 192 193 194 195 196
## -1569.067068 -2347.651539 -10159.509153 -6179.977140 1452.076876
## 197 198 199 200 201
## -5022.654155 -9558.490960 5668.940386 -2819.129267 -1451.525357
## 202 203 204 205 206
## -539.994745 6756.403155 10101.954788 741.445801 3088.239369
## 207 208 209 210 211
## 3249.686602 5924.941734 12950.166729 -5629.719776 -11190.703698
## 212 213 214 215 216
## -5488.356002 -10375.202420 -4806.218129 1816.529133 -12737.838337
## 217 218 219 220 221
## 16725.064754 8041.548877 1714.248540 26867.692668 12560.885742
## 222 223 224 225 226
## 7319.157664 13995.275279 -3995.164988 -1768.084721 3786.836110
## 227 228 229 230 231
## 372.269647 2780.258177 9045.794703 5845.301939 -1896.082878
## 232 233 234 235 236
## -1781.808346 9502.565268 -11465.716208 -7158.510121 -8366.948419
## 237 238 239 240 241
## -9877.213160 3354.396660 1604.484187 -8056.842020 -8707.849097
## 242 243 244 245 246
## 9416.764647 -7506.092998 2782.894307 -10029.448982 -3733.618083
## 247 248 249 250 251
## 1751.686840 1309.537670 -12027.083332 3989.640851 2371.579111
## 252 253 254 255 256
## 4496.516393 2385.836700 -927.788079 11374.046178 21047.763324
## 257 258 259 260 261
## 3245.817689 -4225.679304 4195.508203 -1620.345558 3834.385296
## 262 263 264 265 266
## -4765.158361 -10767.225374 -4532.396243 -298.916822 -4966.152827
## 267 268 269 270 271
## 9026.105523 -4091.125523 4402.466203 -1922.315498 4627.125378
## 272 273 274 275 276
## 876.993318 7467.688139 -1289.880386 12161.320164 -4517.505594
## 277 278 279 280 281
## 1830.436581 -270.569581 7963.139494 -4987.131527 -2617.705424
## 282 283 284 285 286
## -11123.006703 -2455.040145 18882.886103 7889.434702 2798.644246
## 287 288 289 290 291
## -569.132557 982.294958 6479.783239 6933.681562 -18751.067906
## 292 293 294 295 296
## -10976.964083 -7882.076975 9953.886692 3288.599843 -984.757807
## 297 298 299 300 301
## 27604.150371 10084.963039 4872.213450 9481.002962 2781.862040
## 302 303 304 305 306
## -1096.124241 7868.636959 -24350.639184 -3395.884942 -3.677637
## 307 308 309 310 311
## -6790.318951 -3741.862682 3188.403382 -8959.840181 -2935.250233
## 312 313 314 315 316
## -7876.112241 1923.590645 -2818.249271 2390.767701 -3768.387996
## 317 318 319 320 321
## 27776.343490 -618.596800 3410.305514 10933.786444 5625.918317
## 322 323 324 325 326
## 32395.584632 4921.034825 -21115.986418 1806.443160 1134.569847
## 327 328 329 330 331
## -6427.144289 -1630.269852 -33138.307315 1294.727047 -1909.344810
## 332 333 334 335 336
## 304.499693 -2782.371358 4482.022143 -84.445243 -6606.069873
## 337 338 339 340 341
## -2727.591509 -1792.821412 -7278.734643 4294.552084 -977.002407
## 342 343 344 345 346
## -1348.090116 -605.346149 558.604814 848.862408 -1267.137910
## 347 348 349 350 351
## -9094.044129 -12798.471548 2802.324657 -3874.729269 -3198.942436
## 352 353 354 355 356
## -5515.378079 2237.048951 1830.895043 3166.273566 -3394.319150
## 357 358 359 360 361
## -130.930732 1050.049694 7365.883059 561.414841 238.742886
## 362 363 364 365 366
## 2855.713966 -2501.470769 -607.303481 -8468.310018 -4283.205095
## 367 368 369 370 371
## -5841.427835 -4540.820808 -6820.491653 5485.643868 776.785454
## 372 373 374 375 376
## 7504.607247 -7324.078649 -1896.344193 -3014.985388 -2079.326992
## 377 378 379 380 381
## -12063.890824 2380.979262 -10195.859231 6198.765641 9764.331643
## 382 383 384 385 386
## 3457.572072 -2103.514284 1912.348953 7030.580308 11635.728264
## 387 388 389 390 391
## -5671.907637 -5179.460269 71.354942 8791.961917 1972.033330
## 392 393 394 395 396
## 11369.425920 -9817.074907 2929.289029 850.443041 701.832061
## 397 398 399 400 401
## -511.408632 -407.921577 -14321.143201 8819.727759 -956.199375
## 402 403 404 405 406
## -1134.694112 7232.615735 -7740.118376 -1031.205920 -2254.238677
## 407 408 409 410 411
## -5520.518248 -2513.158590 -3554.027857 -8368.374584 6581.712278
## 412 413 414 415 416
## 2016.697832 -7024.336925 -7290.934371 14671.881750 4121.877140
## 417 418 419 420 421
## 4754.600344 -7816.898522 -4454.644214 -2273.933338 3162.910533
## 422 423 424 425 426
## -13700.378546 -2367.323043 -8667.503622 3503.673055 7417.107814
## 427 428 429 430 431
## 6934.792017 -3697.215644 -3801.009209 -4373.956055 -1410.624012
## 432 433 434 435 436
## -5330.354795 -6209.963280 -5494.035112 -908.930617 -376.346352
## 437 438 439 440 441
## -4519.947849 3056.870307 5268.561337 -4688.165929 -1759.643347
## 442 443 444 445 446
## 1977.654473 -3464.925542 3227.508094 -6224.730762 -11712.231322
## 447 448 449 450 451
## -4027.163359 10142.906824 -1639.645039 5149.957208 -5527.334306
## 452 453 454 455 456
## -739.715737 763.888469 3391.237579 -11938.822874 3792.798717
## 457 458 459 460 461
## -6322.001738 6944.365714 3364.309501 2825.336519 -3553.321472
## 462 463 464 465 466
## 2414.445987 291.783387 2089.165641 -242.415877 3632.685698
## 467 468 469 470 471
## -2385.484874 6083.183107 -6711.182902 -2669.842548 -1886.484108
## 472 473 474 475 476
## -4329.451963 3364.363910 8132.020789 -5751.485171 1801.411301
## 477 478 479 480 481
## -5876.705220 -2493.213900 2379.653115 -12587.109062 -9315.059662
## 482 483 484 485 486
## -701.955897 505.797593 -499.676654 -891.953626 -9143.013286
## 487 488 489 490 491
## 11594.994868 6621.886381 7745.126080 -5176.207499 5673.640391
## 492 493 494 495 496
## 9553.578295 6242.105281 -13323.530864 -10292.307409 -3080.457331
## 497 498 499 500 501
## -724.803425 -144.030292 -7251.017514 1038.212234 4695.513890
## 502 503 504 505 506
## 5869.761028 970.000154 383.081107 -6938.076368 927.885004
## 507 508 509 510 511
## -4701.732020 2213.608104 -939.386330 -7797.422103 -184.529637
## 512 513 514 515 516
## -2265.983924 -170.979671 1739.731291 -9111.069874 -7316.825259
## 517 518
## 24777.911748 10102.027914
##
## $fitted.values
## 2 3 4 5 6 7 8 9
## 17225.66 20088.03 24364.70 24081.16 26447.09 23765.51 24485.65 19692.33
## 10 11 12 13 14 15 16 17
## 19427.48 16756.06 17537.68 14249.62 14301.06 14969.26 16674.89 14985.95
## 18 19 20 21 22 23 24 25
## 16026.14 15396.33 22516.55 21595.68 21072.76 22972.85 22295.24 22951.27
## 26 27 28 29 30 31 32 33
## 24807.08 18703.07 20438.44 28317.57 28375.53 28046.70 25663.46 27073.38
## 34 35 36 37 38 39 40 41
## 30936.92 31287.20 32703.90 30201.22 34162.00 37387.19 34427.60 31221.47
## 42 43 44 45 46 47 48 49
## 30063.10 20592.38 28151.21 30600.69 31695.71 38570.28 38062.17 42749.23
## 50 51 52 53 54 55 56 57
## 47008.09 39667.05 34206.54 29202.69 22310.55 28634.11 25196.51 21474.36
## 58 59 60 61 62 63 64 65
## 25906.23 27172.50 27471.09 27885.11 23734.02 40413.79 42267.58 37488.19
## 66 67 68 69 70 71 72 73
## 41717.57 46659.43 57384.50 55387.68 40552.17 38044.73 41078.73 35348.47
## 74 75 76 77 78 79 80 81
## 30776.46 21430.33 24648.87 20552.86 22650.05 17518.36 19544.54 18766.94
## 82 83 84 85 86 87 88 89
## 17789.48 15848.11 17132.70 20759.99 25201.27 26196.42 26221.51 26841.54
## 90 91 92 93 94 95 96 97
## 30988.61 29812.93 30817.61 28871.73 28067.28 28437.39 28846.14 22389.34
## 98 99 100 101 102 103 104 105
## 25420.45 18413.77 17263.80 15294.08 15595.44 16276.43 20772.92 19851.54
## 106 107 108 109 110 111 112 113
## 23381.35 23170.20 24855.26 27747.36 25232.14 21656.66 21933.55 24593.92
## 114 115 116 117 118 119 120 121
## 35516.34 33699.55 35546.82 38561.12 40527.46 38203.56 32996.98 29318.87
## 122 123 124 125 126 127 128 129
## 31412.79 29683.58 30871.43 38511.69 38152.25 37208.79 34055.61 35846.30
## 130 131 132 133 134 135 136 137
## 41272.94 40710.25 31865.08 33136.61 36343.37 32734.89 31113.57 30193.70
## 138 139 140 141 142 143 144 145
## 26732.39 28154.35 27922.75 25596.72 27631.93 26249.37 19817.41 22864.08
## 146 147 148 149 150 151 152 153
## 20679.20 23672.17 24215.03 25813.89 25996.94 27659.91 28967.58 32015.88
## 154 155 156 157 158 159 160 161
## 27461.94 26720.97 24263.21 30188.68 41156.57 39477.91 36828.83 41875.83
## 162 163 164 165 166 167 168 169
## 43291.89 46725.98 42167.77 37449.98 42904.10 59293.05 61516.95 59922.61
## 170 171 172 173 174 175 176 177
## 56731.41 55122.14 57839.09 56858.00 49109.09 51947.62 55710.17 55746.55
## 178 179 180 181 182 183 184 185
## 62913.32 53365.07 50098.72 40858.47 32352.79 35879.72 46036.96 45490.08
## 186 187 188 189 190 191 192 193
## 51474.51 57250.06 68090.42 73401.39 67062.53 67256.99 74364.92 70018.37
## 194 195 196 197 198 199 200 201
## 65517.37 54703.98 48702.35 50134.23 45705.49 37832.63 44291.56 42509.53
## 202 203 204 205 206 207 208 209
## 42145.57 42626.45 49456.62 58393.13 58020.76 59754.74 61419.34 65230.69
## 210 211 212 213 214 215 216 217
## 74747.58 66788.28 54914.50 49494.63 40443.08 37384.61 40514.84 30481.94
## 218 219 220 221 222 223 224 225
## 47545.74 54905.47 55812.16 78698.69 86233.56 88247.44 95879.16 86781.94
## 226 227 228 229 230 231 232 233
## 80748.45 80328.16 76960.31 76117.35 80879.56 82251.08 76656.95 71844.43
## 234 235 236 237 238 239 240 241
## 77528.14 64104.94 56099.09 48006.93 39573.89 43788.09 45952.27 39368.13
## 242 243 244 245 246 247 248 249
## 33014.09 43351.24 37567.53 41524.16 33746.90 32445.88 36120.61 38959.51
## 250 251 252 253 254 255 256 257
## 29740.22 35709.85 39531.48 44753.88 47486.65 46976.53 57332.24 74922.47
## 258 259 260 261 262 263 264 265
## 74736.54 68011.63 69501.35 65702.04 67155.87 60880.37 50097.97 46104.20
## 266 267 268 269 270 271 272 273
## 46314.72 42400.75 51251.70 47504.96 51673.74 49780.30 53869.29 54166.88
## 274 275 276 277 278 279 280 281
## 60216.31 57837.97 67562.36 61454.85 61666.00 60006.29 65779.70 59476.85
## 282 283 284 285 286 287 288 289
## 56022.44 45519.18 43907.40 61231.28 66790.78 67202.42 64606.28 63688.79
## 290 291 292 293 294 295 296 297
## 67711.03 71642.07 52537.54 42586.93 36566.11 46942.40 50201.47 49310.71
## 298 299 300 301 302 303 304 305
## 73635.75 79612.79 80284.00 84921.00 83109.98 78113.79 81599.07 56364.31
## 306 307 308 309 310 311 312 313
## 52605.53 52283.60 46040.72 43235.31 46857.84 39370.39 38085.68 32618.27
## 314 315 316 317 318 319 320 321
## 36422.96 35599.95 39451.82 37425.51 63349.17 61178.84 62811.07 70851.80
## 322 323 324 325 326 327 328 329
## 73251.84 98869.25 97238.27 72939.70 71731.14 70079.72 61988.56 59095.45
## 330 331 332 333 334 335 336 337
## 28883.70 32590.92 33032.79 35365.09 34702.41 40500.16 41581.50 36803.73
## 338 339 340 341 342 343 344 345
## 36013.96 36141.31 31435.31 37466.29 38133.23 38393.06 39273.54 41068.99
## 346 347 348 349 350 351 352 353
## 42900.71 42651.04 35558.04 26075.53 31448.73 30303.66 29891.52 27495.24
## 354 355 356 357 358 359 360 361
## 32199.10 35973.44 40460.89 38640.22 39907.24 42057.12 49491.87 50045.40
## 362 363 364 365 366 367 368 369
## 50248.14 52724.47 50194.45 49636.02 42241.92 39423.71 35580.25 33347.06
## 370 371 372 373 374 375 376 377
## 29383.78 36710.64 39009.82 46937.51 40876.92 40321.13 38850.61 38380.89
## 378 379 380 381 382 383 384 385
## 29199.74 33822.43 26836.95 35100.24 45488.57 49073.09 47337.22 49339.56
## 386 387 388 389 390 391 392 393
## 55592.99 65129.19 58304.17 52742.79 52470.04 59889.11 60415.29 69130.36
## 394 395 396 397 398 399 400 401
## 58177.71 59752.99 59310.74 58791.84 57270.64 56025.57 42713.27 51344.91
## 402 403 404 405 406 407 408 409
## 50339.98 49300.67 55736.26 48238.78 47546.24 45863.95 41518.02 40342.46
## 410 411 412 413 414 415 416 417
## 38395.95 32458.43 40373.45 43315.48 37959.22 33021.12 47972.55 51837.97
## 418 419 420 421 422 423 424 425
## 55788.33 48217.07 44520.65 43189.52 46795.24 35152.18 34879.93 29107.90
## 426 427 428 429 430 431 432 433
## 34727.75 43100.07 50029.22 46777.29 43830.24 40738.91 40626.50 37085.39
## 434 435 436 437 438 439 440 441
## 33203.04 30422.22 32006.77 33866.09 31859.99 36752.30 42991.17 39726.07
## 442 443 444 445 446 447 448 449
## 39430.49 42453.07 40327.78 44338.73 39560.09 30544.16 29375.38 40793.36
## 450 451 452 453 454 455 456 457
## 40473.19 46154.76 41767.43 42118.97 43748.19 47486.39 37306.20 42181.57
## 458 459 460 461 462 463 464 465
## 37580.21 45189.98 48728.95 51363.61 48075.55 50428.93 50631.55 52387.99
## 466 467 468 469 470 471 472 473
## 51882.89 54842.48 52156.39 57234.75 50458.41 48056.48 46635.02 43241.21
## 474 475 476 477 478 479 480 481
## 47017.55 54521.06 48918.02 50630.42 45391.21 43761.49 46609.68 35966.92
## 482 483 484 485 486 487 488 489
## 29493.81 31373.20 34084.39 35582.38 36553.44 30160.01 42757.69 49453.73
## 490 491 492 493 494 495 496 497
## 56320.78 51003.79 55862.85 63537.61 67369.53 53551.88 44079.03 42093.37
## 498 499 500 501 502 503 504 505
## 42418.32 43213.73 37670.79 40082.63 45412.67 51124.86 51838.35 51949.50
## 506 507 508 509 510 511 512 513
## 45617.54 46964.73 43203.82 45974.10 45637.99 39319.96 40457.13 39627.84
## 514 515 516 517 518
## 40739.41 43393.64 36195.25 31449.23 55467.40
##
## $shapiro.test
## [1] 0
##
## $levenes.test
## [1] 0
##
## $autcorr
## [1] "No autocorrelation evidence"
##
## $post_sums
## [1] "Post-Est Warning"
##
## $adjr_sq
## [1] 0.847
##
## $fstat.bootstrap
##
## ORDINARY NONPARAMETRIC BOOTSTRAP
##
##
## Call:
## boot::boot(data = x, statistic = f.stat, R = Reps, formula = depvar ~
## ., parallel = parr)
##
##
## Bootstrap Statistics :
## original bias std. error
## t1* 5.221775 0.5862705 3.076941
## t2* 1701.679428 27.7382805 244.634094
## WARNING: All values of t3* are NA
##
## $itsa.plot
##
## $booted.ints
## Parameter Lower CI Median F-value Upper CI
## 1 interrupt_var 1.631742 5.355771 11.52791
## 2 lag_depvar 1357.209449 1712.740021 2157.87784
Ahora con las tendencias descompuestas
require(zoo)
require(scales)
Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha2=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(gastador=ifelse(gastador=="Andrés",1,0)) %>%
dplyr::mutate(treat=ifelse(fecha2>"2019-W26",1,0)) %>%
dplyr::mutate(gasto= dplyr::case_when(gasto=="Gas"~"Gas/Bencina",
gasto=="aspiradora"~"electrodomésticos/mantención casa",
gasto=="Plata fiestas patrias basureros"~"donaciones/regalos",
gasto=="Tina"~"electrodomésticos/mantención casa",
gasto=="Nexium"~"Farmacia",
gasto=="donaciones"~"donaciones/regalos",
gasto=="Regalo chocolates"~"donaciones/regalos",
gasto=="filtro piscina msp"~"electrodomésticos/mantención casa",
gasto=="Chromecast"~"electrodomésticos/mantención casa",
gasto=="Muebles ratan"~"electrodomésticos/mantención casa",
gasto=="Vacuna Influenza"~"Farmacia",
gasto=="Easy"~"electrodomésticos/mantención casa",
gasto=="Sopapo"~"electrodomésticos/mantención casa",
gasto=="filtro agua"~"electrodomésticos/mantención casa",
gasto=="ropa tami"~"donaciones/regalos",
gasto=="yaz"~"Farmacia",
gasto=="Yaz"~"Farmacia",
gasto=="Remedio"~"Farmacia",
gasto=="Entel"~"VTR",
gasto=="Kerosen"~"Gas/Bencina",
gasto=="Parafina"~"Gas/Bencina",
gasto=="Plata basurero"~"donaciones/regalos",
gasto=="Matri Andrés Kogan"~"donaciones/regalos",
gasto=="Wild Protein"~"Comida",
gasto=="Granola Wild Foods"~"Comida",
gasto=="uber"~"Transporte",
gasto=="Uber Reñaca"~"Transporte",
gasto=="filtro piscina mspa"~"electrodomésticos/mantención casa",
gasto=="Limpieza Alfombra"~"electrodomésticos/mantención casa",
gasto=="Aspiradora"~"electrodomésticos/mantención casa",
gasto=="Limpieza alfombras"~"electrodomésticos/mantención casa",
gasto=="Pila estufa"~"electrodomésticos/mantención casa",
gasto=="Reloj"~"electrodomésticos/mantención casa",
gasto=="Arreglo"~"electrodomésticos/mantención casa",
gasto=="Pan Pepperino"~"Comida",
gasto=="Cookidoo"~"Comida",
gasto=="remedios"~"Farmacia",
gasto=="Bendina Reñaca"~"Gas/Bencina",
gasto=="Bencina Reñaca"~"Gas/Bencina",
gasto=="Vacunas Influenza"~"Farmacia",
gasto=="Remedios"~"Farmacia",
gasto=="Plata fiestas patrias basureros"~"donaciones/regalos",
T~gasto)) %>%
dplyr::group_by(gastador, fecha,gasto, .drop=F) %>%
#dplyr::mutate(fecha_simp=week(parse_date(fecha))) %>%
# dplyr::mutate(fecha_simp=tsibble::yearweek(fecha)) %>%#después de diosi. Junio 24, 2019
dplyr::summarise(monto=sum(monto)) %>%
dplyr::mutate(gastador_nombre=plyr::revalue(as.character(gastador), c("0" = "Tami", "1"="Andrés"))) %>%
ggplot2::ggplot(aes(x = fecha, y = monto, color=as.factor(gastador_nombre))) +
#stat_summary(geom = "line", fun.y = median, size = 1, alpha=0.5, aes(color="blue")) +
geom_line(size=1) +
facet_grid(gasto~.)+
#geom_text(aes(x = fech_ing_qrt, y = perc_dup-0.05, label = paste0(n)), vjust = -1,hjust = 0, angle=45, size=3) +
geom_vline(xintercept = as.Date("2019-06-24"),linetype = "dashed") +
labs(y="Gastos (en miles)",x="Semanas y Meses", subtitle="Interlineado, incorporación de la Diosi; Azul= Tami; Rojo= Andrés") +
ggtitle( "Figura 6. Gastos Semanales por Gastador e ítem (media)") +
scale_y_continuous(labels = f <- function(x) paste0(x/1000)) +
scale_color_manual(name = "Gastador", values= c("blue", "red"), labels = c("Tami", "Andrés")) +
scale_x_yearweek(breaks = "1 month", minor_breaks = "1 week", labels=date_format("%m/%y")) +
guides(color = F)+
sjPlot::theme_sjplot2() +
theme(axis.text.x = element_text(vjust = 0.5,angle = 35)) +
theme(
panel.border = element_blank(),
panel.grid.major = element_blank(),
panel.grid.minor = element_blank(),
axis.line = element_line(colour = "black")
)
autoplot(forecast::mstl(Gastos_casa$monto, lambda = "auto",iterate=5000000,start =
lubridate::decimal_date(as.Date("2019-03-03"))))
# scale_x_continuous(breaks = seq(0,400,by=30))
msts <- forecast::msts(Gastos_casa$monto,seasonal.periods = c(7,30.5,365.25),start =
lubridate::decimal_date(as.Date("2019-03-03")))
#tbats <- forecast::tbats(msts,use.trend = FALSE)
#plot(tbats, main="Multiple Season Decomposition")
library(bsts)
library(CausalImpact)
ts_week_covid<-
Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_week=strftime(fecha, format = "%Y-W%V")) %>%
dplyr::mutate(day=as.Date(as.character(lubridate::floor_date(fecha, "day"))))%>%
dplyr::group_by(fecha_week)%>%
dplyr::summarise(gasto_total=sum(monto,na.rm=T)/1000,min_day=min(day))%>%
dplyr::ungroup() %>%
dplyr::mutate(covid=dplyr::case_when(min_day>=as.Date("2020-03-17")~1,TRUE~0))%>%
dplyr::mutate(covid=as.factor(covid))%>%
data.frame()
ts_week_covid$gasto_total_na<-ts_week_covid$gasto_total
post_resp<-ts_week_covid$gasto_total[which(ts_week_covid$covid==1)]
ts_week_covid$gasto_total_na[which(ts_week_covid$covid==1)]<-NA
ts_week_covid$gasto_total[which(ts_week_covid$covid==0)]
## [1] 98.357 4.780 56.784 50.506 64.483 67.248 49.299 35.786 58.503
## [10] 64.083 20.148 73.476 127.004 81.551 69.599 134.446 58.936 26.145
## [19] 129.927 104.989 130.860 81.893 95.697 64.579 303.471 151.106 49.275
## [28] 76.293 33.940 83.071 119.512 20.942 58.055 71.728 44.090 33.740
## [37] 59.264 77.410 60.831 63.376 48.754 235.284 29.604 115.143 72.419
## [46] 5.980 80.063 149.178 69.918 107.601 72.724 63.203 99.681 130.309
## [55] 195.898 112.066
# Model 1
ssd <- list()
# Local trend, weekly-seasonal #https://qastack.mx/stats/209426/predictions-from-bsts-model-in-r-are-failing-completely - PUSE UN GENERALIZED LOCAL TREND
ssd <- AddLocalLevel(ssd, ts_week_covid$gasto_total_na) #AddSemilocalLinearTrend #AddLocalLevel
# Add weekly seasonal
ssd <- AddSeasonal(ssd, ts_week_covid$gasto_total_na,nseasons=5, season.duration = 52) #weeks OJO, ESTOS NO SON WEEKS VERDADEROS. PORQUE TENGO MAS DE EUN AÑO
ssd <- AddSeasonal(ssd, ts_week_covid$gasto_total_na, nseasons = 12, season.duration =4) #years
# For example, to add a day-of-week component to data with daily granularity, use model.args = list(nseasons = 7, season.duration = 1). To add a day-of-week component to data with hourly granularity, set model.args = list(nseasons = 7, season.duration = 24).
model1d1 <- bsts(ts_week_covid$gasto_total_na,
state.specification = ssd, #A list with elements created by AddLocalLinearTrend, AddSeasonal, and similar functions for adding components of state. See the help page for state.specification.
family ="student", #A Bayesian Analysis of Time-Series Event Count Data. POISSON NO SE PUEDE OCUPAR
niter = 20000,
#burn = 200, #http://finzi.psych.upenn.edu/library/bsts/html/SuggestBurn.html Suggest the size of an MCMC burn in sample as a proportion of the total run.
seed= 2125)
## =-=-=-=-= Iteration 0 Mon Nov 14 01:03:41 2022
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## =-=-=-=-= Iteration 2000 Mon Nov 14 01:03:51 2022
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## =-=-=-=-= Iteration 4000 Mon Nov 14 01:04:00 2022
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## =-=-=-=-= Iteration 10000 Mon Nov 14 01:04:26 2022
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## =-=-=-=-= Iteration 12000 Mon Nov 14 01:04:35 2022
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#,
# dynamic.regression=T)
#plot(model1d1, main = "Model 1")
#plot(model1d1, "components")
impact2d1 <- CausalImpact(bsts.model = model1d1,
post.period.response = post_resp)
plot(impact2d1)+
xlab("Date")+
ylab("Monto Semanal (En miles)")
burn1d1 <- SuggestBurn(0.1, model1d1)
corpus <- Corpus(VectorSource(Gastos_casa$obs)) # formato de texto
d <- tm_map(corpus, tolower)
d <- tm_map(d, stripWhitespace)
d <- tm_map(d, removePunctuation)
d <- tm_map(d, removeNumbers)
d <- tm_map(d, removeWords, stopwords("spanish"))
d <- tm_map(d, removeWords, "menos")
tdm <- TermDocumentMatrix(d)
m <- as.matrix(tdm) #lo vuelve una matriz
v <- sort(rowSums(m),decreasing=TRUE) #lo ordena y suma
df <- data.frame(word = names(v),freq=v) # lo nombra y le da formato de data.frame
#findFreqTerms(tdm)
#require(devtools)
#install_github("lchiffon/wordcloud2")
#wordcloud2::wordcloud2(v, size=1.2)
wordcloud(words = df$word, freq = df$freq,
max.words=100, random.order=FALSE, rot.per=0.35,
colors=brewer.pal(8, "Dark2"), main="Figura 7. Nube de Palabras, Observaciones")
fit_month_gasto <- Gastos_casa %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_month=strftime(fecha, format = "%Y-%m")) %>%
dplyr::mutate(day=as.Date(as.character(lubridate::floor_date(fecha, "day"))))%>%
dplyr::mutate(gasto2= dplyr::case_when(gasto=="Gas"~"Gas/Bencina",
gasto=="aspiradora"~"electrodomésticos/mantención casa",
gasto=="Plata fiestas patrias basureros"~"donaciones/regalos",
gasto=="Tina"~"Electrodomésticos/ Mantención casa",
gasto=="Nexium"~"Farmacia",
gasto=="donaciones"~"donaciones/regalos",
gasto=="Regalo chocolates"~"donaciones/regalos",
gasto=="filtro piscina msp"~"Electrodomésticos/ Mantención casa",
gasto=="Chromecast"~"Electrodomésticos/ Mantención casa",
gasto=="Muebles ratan"~"Electrodomésticos/ Mantención casa",
gasto=="Vacuna Influenza"~"Farmacia",
gasto=="Easy"~"Electrodomésticos/ Mantención casa",
gasto=="Sopapo"~"Electrodomésticos/ Mantención casa",
gasto=="filtro agua"~"Electrodomésticos/ Mantención casa",
gasto=="ropa tami"~"donaciones/regalos",
gasto=="yaz"~"Farmacia",
gasto=="Yaz"~"Farmacia",
gasto=="Remedio"~"Farmacia",
gasto=="Entel"~"VTR",
gasto=="Kerosen"~"Gas/Bencina",
gasto=="Parafina"~"Gas/Bencina",
gasto=="Plata basurero"~"donaciones/regalos",
gasto=="Matri Andrés Kogan"~"donaciones/regalos",
gasto=="Wild Protein"~"Comida",
gasto=="Granola Wild Foods"~"Comida",
gasto=="uber"~"Otros",
gasto=="Uber Reñaca"~"Otros",
gasto=="filtro piscina mspa"~"Electrodomésticos/ Mantención casa",
gasto=="Limpieza Alfombra"~"Electrodomésticos/ Mantención casa",
gasto=="Aspiradora"~"Electrodomésticos/ Mantención casa",
gasto=="Limpieza alfombras"~"Electrodomésticos/ Mantención casa",
gasto=="Pila estufa"~"Electrodomésticos/ Mantención casa",
gasto=="Reloj"~"Electrodomésticos/ Mantención casa",
gasto=="Arreglo"~"Electrodomésticos/ Mantención casa",
gasto=="Pan Pepperino"~"Comida",
gasto=="Cookidoo"~"Comida",
gasto=="remedios"~"Farmacia",
gasto=="Bendina Reñaca"~"Gas/Bencina",
gasto=="Bencina Reñaca"~"Gas/Bencina",
gasto=="Vacunas Influenza"~"Farmacia",
gasto=="Remedios"~"Farmacia",
gasto=="Plata fiestas patrias basureros"~"donaciones/regalos",
T~gasto)) %>%
dplyr::mutate(fecha_month=factor(fecha_month, levels=format(seq(from = as.Date("2019-03-03"), to = as.Date(substr(Sys.time(),1,10)), by = "1 month"),"%Y-%m")))%>%
dplyr::mutate(gasto2=factor(gasto2, levels=c("Agua", "Comida", "Comunicaciones","Electricidad", "Enceres", "Farmacia", "Gas/Bencina", "Diosi", "donaciones/regalos", "Electrodomésticos/ Mantención casa", "VTR", "Netflix", "Otros")))%>%
dplyr::group_by(fecha_month, gasto2, .drop=F)%>%
dplyr::summarise(gasto_total=sum(monto, na.rm = T)/1000)%>%
data.frame() %>% na.omit()
fit_month_gasto_23<-
fit_month_gasto %>%
#dplyr::filter()
dplyr::filter(grepl("2023",fecha_month)) %>%
#sacar el ultimo mes
dplyr::filter(as.character(format(as.Date(substr(Sys.time(),1,10)),"%Y-%m"))!=fecha_month) %>%
dplyr::group_by(gasto2) %>%
dplyr::summarise(gasto_prom=mean(gasto_total, na.rm=T)) %>%
data.frame()%>% ungroup()
fit_month_gasto_22<-
fit_month_gasto %>%
#dplyr::filter()
dplyr::filter(grepl("2022",fecha_month)) %>%
#sacar el ultimo mes
dplyr::filter(as.character(format(as.Date(substr(Sys.time(),1,10)),"%Y-%m"))!=fecha_month) %>%
dplyr::group_by(gasto2) %>%
dplyr::summarise(gasto_prom=mean(gasto_total, na.rm=T)) %>%
data.frame()%>% ungroup()
fit_month_gasto_21<-
fit_month_gasto %>%
#dplyr::filter()
dplyr::filter(grepl("2021|2022",fecha_month)) %>%
#sacar el ultimo mes
dplyr::filter(as.character(format(as.Date(substr(Sys.time(),1,10)),"%Y-%m"))!=fecha_month) %>%
dplyr::group_by(gasto2) %>%
dplyr::summarise(gasto_prom=mean(gasto_total, na.rm=T)) %>%
data.frame()%>% ungroup()
fit_month_gasto_20<-
fit_month_gasto %>%
#dplyr::filter()
dplyr::filter(grepl("202",fecha_month)) %>%
#sacar el ultimo mes
dplyr::filter(as.character(format(as.Date(substr(Sys.time(),1,10)),"%Y-%m"))!=fecha_month) %>%
dplyr::group_by(gasto2) %>%
dplyr::summarise(gasto_prom=mean(gasto_total, na.rm=T)) %>%
data.frame() %>% ungroup()
fit_month_gasto_23 %>%
dplyr::right_join(fit_month_gasto_22,by="gasto2") %>%
dplyr::right_join(fit_month_gasto_21,by="gasto2") %>%
dplyr::right_join(fit_month_gasto_20,by="gasto2") %>%
janitor::adorn_totals() %>%
#dplyr::select(-3)%>%
knitr::kable(format = "markdown", size=12, col.names= c("Item","2023","2022","2021","2020"))
| Item | 2023 | 2022 | 2021 | 2020 |
|---|---|---|---|---|
| Agua | NA | 5.4832 | 5.682818 | 7.184559 |
| Comida | NA | 309.9132 | 314.267773 | 342.032206 |
| Comunicaciones | NA | 0.0000 | 0.000000 | 0.000000 |
| Electricidad | NA | 43.8829 | 36.050227 | 30.598824 |
| Enceres | NA | 22.4051 | 18.257500 | 25.582618 |
| Farmacia | NA | 2.1980 | 8.633318 | 10.540412 |
| Gas/Bencina | NA | 45.5550 | 28.116091 | 24.283941 |
| Diosi | NA | 14.5163 | 35.337136 | 35.966853 |
| donaciones/regalos | NA | 0.0000 | 7.821909 | 8.079971 |
| Electrodomésticos/ Mantención casa | NA | 4.7328 | 33.021273 | 24.396118 |
| VTR | NA | 25.7900 | 22.133773 | 21.067882 |
| Netflix | NA | 6.9259 | 6.982000 | 7.428559 |
| Otros | NA | 3.7813 | 1.718773 | 1.112147 |
| Total | 0 | 485.1837 | 518.022591 | 538.274088 |
## Joining, by = "word"
Saqué la UF proyectada
#options(max.print=5000)
uf18 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2018.htm")%>% rvest::html_nodes("table")
uf19 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2019.htm")%>% rvest::html_nodes("table")
uf20 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2020.htm")%>% rvest::html_nodes("table")
uf21 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2021.htm")%>% rvest::html_nodes("table")
uf22 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2022.htm")%>% rvest::html_nodes("table")
tryCatch(uf23 <-rvest::read_html("https://www.sii.cl/valores_y_fechas/uf/uf2023.htm")%>% rvest::html_nodes("table"),
error = function(c) {
uf23b <<- cbind.data.frame(Día=NA, variable=NA, value=NA)
}
)
tryCatch(uf23 <-uf23[[length(uf23)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1),
error = function(c) {
uf23 <<- cbind.data.frame(Día=NA, variable=NA, value=NA)
}
)
uf_serie<-
bind_rows(
cbind.data.frame(anio= 2018, uf18[[length(uf18)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1)),
cbind.data.frame(anio= 2019, uf19[[length(uf19)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1)),
cbind.data.frame(anio= 2020, uf20[[length(uf20)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1)),
cbind.data.frame(anio= 2021, uf21[[length(uf21)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1)),
cbind.data.frame(anio= 2022, uf22[[length(uf22)]] %>% rvest::html_table() %>% data.frame() %>% reshape2::melt(id.vars=1)),
cbind.data.frame(anio= 2023, uf23)
)
uf_serie_corrected<-
uf_serie %>%
dplyr::mutate(month=plyr::revalue(tolower(.[[3]]),c("ene" = 1, "feb"=2, "mar"=3, "abr"=4, "may"=5, "jun"=6, "jul"=7, "ago"=8, "sep"=9, "oct"=10, "nov"=11, "dic"=12))) %>%
dplyr::mutate(value=stringr::str_trim(value), value= sub("\\.","",value),value= as.numeric(sub("\\,",".",value))) %>%
dplyr::mutate(date=paste0(sprintf("%02d", .[[2]])," ",sprintf("%02d",as.numeric(month)),", ",.[[1]]), date3=lubridate::parse_date_time(date,c("%d %m, %Y"),exact=T),date2=date3) %>%
na.omit()#%>% dplyr::filter(is.na(date3))
## Warning: 35 failed to parse.
#Day of the month as decimal number (1–31), with a leading space for a single-digit number.
#Abbreviated month name in the current locale on this platform. (Also matches full name on input: in some locales there are no abbreviations of names.)
warning(paste0("number of observations:",nrow(uf_serie_corrected),", min uf: ",min(uf_serie_corrected$value),", min date: ",min(uf_serie_corrected $date3 )))
## Warning: number of observations:1804, min uf: 26799.01, min date: 2018-01-01
#
# uf_proyectado <- readxl::read_excel("uf_proyectado.xlsx") %>% dplyr::arrange(Período) %>%
# dplyr::mutate(Período= as.Date(lubridate::parse_date_time(Período, c("%Y-%m-%d"),exact=T)))
ts_uf_proy<-
ts(data = uf_serie_corrected$value,
start = as.numeric(as.Date("2018-01-01")),
end = as.numeric(as.Date(uf_serie_corrected$date3[length(uf_serie_corrected$date3)])), frequency = 1,
deltat = 1, ts.eps = getOption("ts.eps"))
fit_tbats <- forecast::tbats(ts_uf_proy)
fr_fit_tbats<-forecast::forecast(fit_tbats, h=298)
La proyección de la UF a 298 días más 2022-12-09 00:04:58 sería de: 35.506 pesos// Percentil 95% más alto proyectado: 38.720,43
Ahora con un modelo ARIMA automático
arima_optimal_uf = forecast::auto.arima(ts_uf_proy)
autoplotly::autoplotly(forecast::forecast(arima_optimal_uf, h=298), ts.colour = "darkred",
predict.colour = "blue", predict.linetype = "dashed")%>%
plotly::layout(showlegend = F,
yaxis = list(title = "Gastos"),
xaxis = list(
title="Fecha",
ticktext = as.list(seq(from = as.Date("2018-01-01"),
to = as.Date("2018-01-01")+length(fit_tbats$fitted.values)+298, by = 90)),
tickvals = as.list(seq(from = as.numeric(as.Date("2018-01-01")),
to = as.numeric(as.Date("2018-01-01"))+length(fit_tbats$fitted.values)+298, by = 90)),
tickmode = "array",
tickangle = 90
))
fr_fit_tbats_uf<-forecast::forecast(arima_optimal_uf, h=298)
dplyr::group_by(reshape2::melt(data.frame(fr_fit_tbats)),variable) %>% dplyr::summarise(max=max(value)) %>%
dplyr::right_join(dplyr::group_by(reshape2::melt(data.frame(fr_fit_tbats_uf)),variable) %>% dplyr::summarise(max=max(value)),by="variable") %>%
dplyr::mutate(variable=factor(variable,levels=c("Lo.95","Lo.80","Point.Forecast","Hi.80","Hi.95"))) %>%
dplyr::arrange(variable) %>%
knitr::kable(format="markdown", caption="Tabla. Estimación UF (de aquí a 298 días) según cálculos de gastos mensuales",
col.names= c("Item","UF Proyectada (TBATS)","UF Proyectada (ARIMA)"))
## No id variables; using all as measure variables
## No id variables; using all as measure variables
| Item | UF Proyectada (TBATS) | UF Proyectada (ARIMA) |
|---|---|---|
| Lo.95 | 34884.62 | 34876.56 |
| Lo.80 | 34911.29 | 34897.34 |
| Point.Forecast | 35505.54 | 36589.34 |
| Hi.80 | 37282.91 | 41179.92 |
| Hi.95 | 38259.54 | 43610.02 |
Lo haré en base a 2 cálculos: el gasto semanal y el gasto mensual en base a mis gastos desde marzo de 2019. La primera proyección la hice añadiendo el precio del arriendo mensual y partiendo en 2 (porque es con yo y Tami). No se incluye el último mes.
Gastos_casa_nvo <- readr::read_csv(as.character(path_sec),
col_names = c("Tiempo", "gasto", "fecha", "obs", "monto", "gastador",
"link"),skip=1) %>%
dplyr::mutate(fecha= lubridate::parse_date_time(fecha, c("%d/%m/%Y"),exact=T)) %>%
dplyr::mutate(fecha_month=strftime(fecha, format = "%Y-%m")) %>%
dplyr::mutate(day=as.Date(as.character(lubridate::floor_date(fecha, "day"))))
Gastos_casa_m <-
Gastos_casa_nvo %>% dplyr::group_by(fecha_month)%>%
dplyr::summarise(gasto_total=(sum(monto)+500000)/1000,fecha=first(fecha))%>%
data.frame()
uf_serie_corrected_m <-
uf_serie_corrected %>% dplyr::mutate(ano_m=paste0(anio,"-",sprintf("%02d",as.numeric(month)))) %>% dplyr::group_by(ano_m)%>%
dplyr::summarise(uf=(mean(value))/1000,fecha=first(date3))%>%
data.frame() %>%
dplyr::filter(fecha>="2019-02-28")
#Error: Error in standardise_path(file) : object 'enlace_gastos' not found
ts_uf_serie_corrected_m<-
ts(data = uf_serie_corrected_m$uf[-length(uf_serie_corrected_m$uf)],
start = 1,
end = nrow(uf_serie_corrected_m),
frequency = 1,
deltat = 1, ts.eps = getOption("ts.eps"))
ts_gastos_casa_m<-
ts(data = Gastos_casa_m$gasto_total[-length(Gastos_casa_m$gasto_total)],
start = 1,
end = nrow(Gastos_casa_m),
frequency = 1,
deltat = 1, ts.eps = getOption("ts.eps"))
fit_tbats_m <- forecast::tbats(ts_gastos_casa_m)
seq_dates<-format(seq(as.Date("2019/03/01"), by = "month", length = dim(Gastos_casa_m)[1]+12), "%m\n'%y")
autplo2t<-
autoplotly::autoplotly(forecast::forecast(fit_tbats_m, h=12), ts.colour = "darkred",
predict.colour = "blue", predict.linetype = "dashed")%>%
plotly::layout(showlegend = F,
yaxis = list(title = "Gastos (en miles)"),
xaxis = list(
title="Fecha",
ticktext = as.list(seq_dates[seq(from = 1, to = (dim(Gastos_casa_m)[1]+12), by = 3)]),
tickvals = as.list(seq(from = 1, to = (dim(Gastos_casa_m)[1]+12), by = 3)),
tickmode = "array"#"array"
))
autplo2t
Ahora asumiendo un modelo ARIMA, e incluimos como regresor al precio de la UF.
paste0("Optimo pero sin regresor")
## [1] "Optimo pero sin regresor"
arima_optimal = forecast::auto.arima(ts_gastos_casa_m)
arima_optimal
## Series: ts_gastos_casa_m
## ARIMA(1,0,0) with non-zero mean
##
## Coefficients:
## ar1 mean
## 0.3170 990.6885
## s.e. 0.1473 35.2789
##
## sigma^2 = 27645: log likelihood = -292.99
## AIC=591.99 AICc=592.57 BIC=597.41
paste0("Optimo pero con regresor")
## [1] "Optimo pero con regresor"
arima_optimal2 = forecast::auto.arima(ts_gastos_casa_m, xreg=as.numeric(ts_uf_serie_corrected_m[1:(length(Gastos_casa_m$gasto_total))]))
arima_optimal2
## Series: ts_gastos_casa_m
## Regression with ARIMA(1,0,0) errors
##
## Coefficients:
## ar1 intercept xreg
## 0.3143 874.785 3.8838
## s.e. 0.1479 516.143 17.2520
##
## sigma^2 = 28272: log likelihood = -292.97
## AIC=593.94 AICc=594.94 BIC=601.16
forecast_uf<-
cbind.data.frame(fecha=as.Date(seq(as.numeric(as.Date(uf_serie_corrected$date3[length(uf_serie_corrected$date3)])),(as.numeric(as.Date(uf_serie_corrected$date3[length(uf_serie_corrected$date3)]))+299),by=1), origin = "1970-01-01"),forecast::forecast(fit_tbats, h=300)) %>%
dplyr::mutate(ano_m=stringr::str_extract(fecha,".{7}")) %>%
dplyr::group_by(ano_m)%>%
dplyr::summarise(uf=(mean(`Hi 95`,na.rm=T))/1000,fecha=first(fecha))%>%
data.frame()
autplo2t2<-
autoplotly::autoplotly(forecast::forecast(arima_optimal2,xreg=c(forecast_uf$uf[1],forecast_uf$uf), h=12), ts.colour = "darkred",
predict.colour = "blue", predict.linetype = "dashed")%>%
plotly::layout(showlegend = F,
yaxis = list(title = "Gastos (en miles)"),
xaxis = list(
title="Fecha",
ticktext = as.list(seq_dates[seq(from = 1, to = (dim(Gastos_casa_m)[1]+12), by = 3)]),
tickvals = as.list(seq(from = 1, to = (dim(Gastos_casa_m)[1]+12), by = 3)),
tickmode = "array"#"array"
))
autplo2t2
fr_fit_tbats_m<-forecast::forecast(fit_tbats_m, h=12)
fr_fit_tbats_m2<-forecast::forecast(arima_optimal, h=12)
fr_fit_tbats_m3<-forecast::forecast(arima_optimal2, h=12,xreg=c(forecast_uf$uf[1],forecast_uf$uf))
dplyr::right_join(dplyr::group_by(reshape2::melt(data.frame(fr_fit_tbats_m3)),variable) %>% dplyr::summarise(max=max(value)), dplyr::group_by(reshape2::melt(data.frame(fr_fit_tbats_m2)),variable) %>% dplyr::summarise(max=max(value)),by="variable") %>%
dplyr::right_join(dplyr::group_by(reshape2::melt(data.frame(fr_fit_tbats_m)),variable) %>% dplyr::summarise(max=max(value)),by="variable") %>%
dplyr::mutate(variable=factor(variable,levels=c("Lo.95","Lo.80","Point.Forecast","Hi.80","Hi.95"))) %>%
dplyr::arrange(variable) %>%
knitr::kable(format="markdown", caption="Estimación en miles de la plata a gastar en el futuro (de aquí a 12 meses) según cálculos de gastos mensuales",
col.names= c("Item","Modelo ARIMA con regresor (UF)","Modelo ARIMA sin regresor","Modelo TBATS"))
## No id variables; using all as measure variables
## No id variables; using all as measure variables
## No id variables; using all as measure variables
| Item | Modelo ARIMA con regresor (UF) | Modelo ARIMA sin regresor | Modelo TBATS |
|---|---|---|---|
| Lo.95 | 676.2442 | 647.0860 | 684.8307 |
| Lo.80 | 796.4056 | 766.0188 | 765.4038 |
| Point.Forecast | 1023.3958 | 990.6883 | 944.3703 |
| Hi.80 | 1250.3860 | 1215.3577 | 1236.6942 |
| Hi.95 | 1370.5474 | 1334.2906 | 1426.4585 |
path_sec2<- paste0("https://docs.google.com/spreadsheets/d/",Sys.getenv("SUPERSECRET"),"/export?format=csv&id=",Sys.getenv("SUPERSECRET"),"&gid=847461368")
Gastos_casa_mensual_2022 <- readr::read_csv(as.character(path_sec2),
#col_names = c("Tiempo", "gasto", "fecha", "obs", "monto", "gastador","link"),
skip=0)
## Rows: 42 Columns: 4
## -- Column specification --------------------------------------------------------
## Delimiter: ","
## chr (1): mes_ano
## dbl (3): n, Andrés, Tami
##
## i Use `spec()` to retrieve the full column specification for this data.
## i Specify the column types or set `show_col_types = FALSE` to quiet this message.
head(Gastos_casa_mensual_2022,5) %>%
knitr::kable("markdown",caption="Resumen mensual, primeras 5 observaciones")
| n | mes_ano | Andrés | Tami |
|---|---|---|---|
| 1 | marzo_2019 | 68268 | 175533 |
| 2 | abril_2019 | 55031 | 152640 |
| 3 | mayo_2019 | 192219 | 152985 |
| 4 | junio_2019 | 84961 | 291067 |
| 5 | julio_2019 | 205893 | 241389 |
(
Gastos_casa_mensual_2022 %>%
reshape2::melt(id.var=c("n","mes_ano")) %>%
dplyr::mutate(gastador=as.factor(variable)) %>%
dplyr::select(-variable) %>%
ggplot2::ggplot(aes(x = n, y = value, color=gastador)) +
scale_color_manual(name="Gastador", values=c("red", "blue"))+
geom_line(size=1) +
#geom_vline(xintercept = as.Date("2019-06-24"),linetype = "dashed") +
labs(y="Gastos (en miles)",x="Meses", subtitle="Azul= Tami; Rojo= Andrés") +
ggtitle( "Gastos Mensuales (total manual)") +
scale_y_continuous(labels = f <- function(x) paste0(x/1000)) +
# scale_color_manual(name = "Gastador", values= c("blue", "red"), labels = c("Tami", "Andrés")) +
# scale_x_yearweek(breaks = "1 month", minor_breaks = "1 week", labels=date_format("%m/%y")) +
# guides(color = F)+
sjPlot::theme_sjplot2() +
theme(axis.text.x = element_text(vjust = 0.5,angle = 35)) +
theme(
panel.border = element_blank(),
panel.grid.major = element_blank(),
panel.grid.minor = element_blank(),
axis.line = element_line(colour = "black")
)
) %>% ggplotly()
Sys.getenv("R_LIBS_USER")
## [1] "D:\\a\\_temp\\Library"
sessionInfo()
## R version 4.1.2 (2021-11-01)
## Platform: x86_64-w64-mingw32/x64 (64-bit)
## Running under: Windows Server x64 (build 20348)
##
## Matrix products: default
##
## locale:
## [1] LC_COLLATE=Spanish_Chile.1252 LC_CTYPE=Spanish_Chile.1252
## [3] LC_MONETARY=Spanish_Chile.1252 LC_NUMERIC=C
## [5] LC_TIME=Spanish_Chile.1252
##
## attached base packages:
## [1] grid stats graphics grDevices utils datasets methods
## [8] base
##
## other attached packages:
## [1] CausalImpact_1.3.0 bsts_0.9.9 BoomSpikeSlab_1.2.5
## [4] Boom_0.9.11 scales_1.2.1 ggiraph_0.8.3
## [7] tidytext_0.3.4 DT_0.26 autoplotly_0.1.4
## [10] rvest_1.0.3 plotly_4.10.1 xts_0.12.2
## [13] forecast_8.18 wordcloud_2.6 RColorBrewer_1.1-3
## [16] SnowballC_0.7.0 tm_0.7-9 NLP_0.2-1
## [19] tsibble_1.1.3 forcats_0.5.2 dplyr_1.0.10
## [22] purrr_0.3.5 tidyr_1.2.1 tibble_3.1.8
## [25] ggplot2_3.4.0 tidyverse_1.3.2 sjPlot_2.8.11
## [28] lattice_0.20-45 gridExtra_2.3 plotrix_3.8-2
## [31] sparklyr_1.7.8 httr_1.4.4 readxl_1.4.1
## [34] zoo_1.8-11 stringr_1.4.1 stringi_1.7.8
## [37] DataExplorer_0.8.2 data.table_1.14.4 reshape2_1.4.4
## [40] fUnitRoots_4021.80 plyr_1.8.8 readr_2.1.3
##
## loaded via a namespace (and not attached):
## [1] utf8_1.2.2 tidyselect_1.2.0 lme4_1.1-31
## [4] htmlwidgets_1.5.4 munsell_0.5.0 codetools_0.2-18
## [7] effectsize_0.8.2 its.analysis_1.6.0 withr_2.5.0
## [10] colorspace_2.0-3 ggfortify_0.4.15 highr_0.9
## [13] knitr_1.40 uuid_1.1-0 rstudioapi_0.14
## [16] TTR_0.24.3 labeling_0.4.2 emmeans_1.8.2
## [19] slam_0.1-50 bit64_4.0.5 farver_2.1.1
## [22] datawizard_0.6.3 fBasics_4021.93 rprojroot_2.0.3
## [25] vctrs_0.5.0 generics_0.1.3 xfun_0.34
## [28] timechange_0.1.1 R6_2.5.1 bitops_1.0-7
## [31] cachem_1.0.6 assertthat_0.2.1 networkD3_0.4
## [34] vroom_1.6.0 nnet_7.3-16 googlesheets4_1.0.1
## [37] gtable_0.3.1 spatial_7.3-14 timeDate_4021.106
## [40] rlang_1.0.6 forge_0.2.0 systemfonts_1.0.4
## [43] splines_4.1.2 lazyeval_0.2.2 gargle_1.2.1
## [46] selectr_0.4-2 broom_1.0.1 yaml_2.3.6
## [49] abind_1.4-5 modelr_0.1.10 crosstalk_1.2.0
## [52] backports_1.4.1 quantmod_0.4.20 tokenizers_0.2.3
## [55] tools_4.1.2 ellipsis_0.3.2 gplots_3.1.3
## [58] jquerylib_0.1.4 Rcpp_1.0.9 base64enc_0.1-3
## [61] fracdiff_1.5-2 haven_2.5.1 fs_1.5.2
## [64] magrittr_2.0.3 timeSeries_4021.105 lmtest_0.9-40
## [67] reprex_2.0.2 googledrive_2.0.0 mvtnorm_1.1-3
## [70] sjmisc_2.8.9 hms_1.1.2 evaluate_0.18
## [73] xtable_1.8-4 sjstats_0.18.1 ggeffects_1.1.4
## [76] compiler_4.1.2 KernSmooth_2.23-20 crayon_1.5.2
## [79] minqa_1.2.5 htmltools_0.5.3 tzdb_0.3.0
## [82] lubridate_1.9.0 DBI_1.1.3 sjlabelled_1.2.0
## [85] dbplyr_2.2.1 MASS_7.3-54 boot_1.3-28
## [88] Matrix_1.5-3 car_3.1-1 cli_3.4.1
## [91] quadprog_1.5-8 parallel_4.1.2 insight_0.18.6
## [94] igraph_1.3.5 pkgconfig_2.0.3 xml2_1.3.3
## [97] bslib_0.4.1 estimability_1.4.1 anytime_0.3.9
## [100] snakecase_0.11.0 janeaustenr_1.0.0 digest_0.6.30
## [103] parameters_0.19.0 janitor_2.1.0 rmarkdown_2.18
## [106] cellranger_1.1.0 curl_4.3.3 gtools_3.9.3
## [109] urca_1.3-3 nloptr_2.0.3 lifecycle_1.0.3
## [112] nlme_3.1-153 jsonlite_1.8.3 tseries_0.10-52
## [115] carData_3.0-5 viridisLite_0.4.1 fansi_1.0.3
## [118] pillar_1.8.1 fastmap_1.1.0 glue_1.6.2
## [121] bayestestR_0.13.0 bit_4.0.4 sass_0.4.2
## [124] performance_0.10.0 r2d3_0.2.6 caTools_1.18.2
#save.image("__analisis.RData")
sesion_info <- devtools::session_info()
dplyr::select(
tibble::as_tibble(sesion_info$packages),
c(package, loadedversion, source)
) %>%
DT::datatable(filter = 'top', colnames = c('Row number' =1,'Variable' = 2, 'Percentage'= 3),
caption = htmltools::tags$caption(
style = 'caption-side: top; text-align: left;',
'', htmltools::em('Packages')),
options=list(
initComplete = htmlwidgets::JS(
"function(settings, json) {",
"$(this.api().tables().body()).css({
'font-family': 'Helvetica Neue',
'font-size': '50%',
'code-inline-font-size': '15%',
'white-space': 'nowrap',
'line-height': '0.75em',
'min-height': '0.5em'
});",#;
"}")))